5th International ICST Conference on Body Area Networks

Research Article

An Ultra Wideband Propagation Model for Wireless Cardiac Monitoring Devices

  • @INPROCEEDINGS{10.1145/2221924.2221947,
        author={Raul Chavez-Santiago and Ali Khaleghi and Ilangko Balasingham},
        title={An Ultra Wideband Propagation Model for Wireless Cardiac Monitoring Devices},
        proceedings={5th International ICST Conference on Body Area Networks},
        publisher={ACM},
        proceedings_a={BODYNETS},
        year={2012},
        month={6},
        keywords={In-body communication. Ultra wideband. Radio propagation.},
        doi={10.1145/2221924.2221947}
    }
    
  • Raul Chavez-Santiago
    Ali Khaleghi
    Ilangko Balasingham
    Year: 2012
    An Ultra Wideband Propagation Model for Wireless Cardiac Monitoring Devices
    BODYNETS
    ACM
    DOI: 10.1145/2221924.2221947
Raul Chavez-Santiago1,*, Ali Khaleghi1, Ilangko Balasingham1
  • 1: The Interventional Centre, Oslo University Hospital
*Contact email: raul.chavez-santiago@rr-research.no

Abstract

Wireless communication is an important technology to improve e-health applications such as remote cardiac monitoring. In modern telemedicine it is desirable that implant cardiac devices such as pacemakers can be interrogated and reprogrammed remotely. Such functions require a reliable wireless communication channel between the implant device and an external control unit. In order to increase the longevity of the implant device, the communication link must consume extremely low power. The use of ultra wideband (UWB) signals for this wireless link can fulfill the above requirements. However, little is known about the propagation of UWB signals inside the human body, despite the enormous research effort that has recently been devoted to the characterization of the on-body UWB radio communication channel. This paper presents a propagation model of UWB signals through the human chest in the 1–6 GHz frequency band. This is based on numerical simulations using a heterogeneous anatomical model with frequency dependent tissue material properties. The provided model is suitable for the design of UWB in-body communication links for wireless cardiac monitoring devices.